Experimental Study of Amphibolite–Basalt (SiO2-AlO3-CaO-Fe2O3) Glasses for Glass-Ceramic Materials Production

The paper presents research on multicomponent glasses obtained from natural and secondary raw materials, i.e., basalt, amphibolite, and cullet. The raw materials were used as potential sets to produce mineral fibres or glass-ceramic materials. FTIR spectroscopy and XRD studies were carried out to identify the composition of the phase type in the glass sets. The results were supported by SEM-EDS microstructural studies of the obtained materials. The ability of the melts to crystallize and their basic properties required in producing mineral fibres, i.e., the hardness and the acidity modulus, were also determined. In the glass samples after the crystallization process, the spectroscopic studies revealed an increase in the half-width of the band at 1200–800 cm−1 and splitting at the values of about 870 cm−1 and 970 cm−1. These changes probably indicate the formation of pyroxene-type crystalline phases. Moreover, based on the XRD results, it was confirmed that the obtained materials were fully amorphous. After annealing at 800 °C for 2 h, the materials show a small proportion of crystalline phases. For the materials annealed at higher temperatures, clear peaks from the crystalline phases were represented mainly by pyroxenes. The proportion of crystalline phases in the samples was also found to rise with increasing temperature, and the hardness values for the basalt glasses and glasses after crystallization rose from 753 to 946 HV0.05. Such an effect positively affects the properties of the obtained glass-ceramic materials based on the proposed sets. However, in the case of mineral fibres, crystallization at early 2 h at 800 °C can be a disadvantageous feature from the point of view of their application because crystalline phases can lead to fibre damage after a short period of operation; this will be confirmed in this study.


Introduction
The fast development of glass materials technology and more innovative solutions in building insulation systems to obtain adequate acoustic levels, construction fire, and thermal insulation requires using novel mineral fibre elements and manufacturing new glass or glass-ceramic materials [1][2][3].The most commonly used material for mineral wool is basalt, which is a mafic, extrusive rock that makes up more than 90% of all volcanic rocks.It has a crystalline structure that changes depending on the specific conditions of the lava flow.Basalts mainly consist of three minerals-pyroxene, olivine, and plagioclase [4,5].This raw material is mainly used as road aggregate and for producing plates and tiles, linings for steel pipes, etc.In recent years, basalts have also been used to produce bricks and mineral basalt fibres, which, recently, with great success, have even found architectural applications However, the production of glass-ceramics required the use of nucleating agents.Using these agents undoubtedly increases the cost of glass-ceramics production and reduces its commercial profitability, transportation, and stone processing.In the case of a glass cullet, it can be recycled entirely to exploit alternatives to its final disposal.They could be used as additives in asphalt and concrete production [31,32].As a technical alternative, the author's research works have glass cullet used in obtaining glass-ceramics, bearing in mind that these materials may have attractive properties for applications in several industrial sectors.
Additionally, glass-ceramic technology represents a versatile (materials science) approach to immobilizing various radioactive and dangerous wastes.However, due to the high melting temperatures and special heat treatment conditions required to reach adequate properties of glass-ceramics, waste can only be justified if high-value products with suitable properties for industrial applications can be developed [33,34].Savvilotidou et al. [35] presented a study that investigates an innovative approach for valorizing specific wastes generated from the energy sector and producing glass-ceramics.The wastes used were photovoltaic (P/V) glass, produced from the renewable energy sector, and lignite fly ash, produced from the conventional energy sector.The process first involved the production of glass after melting specific mixtures of wastes, namely (i) 70% P/V glass and 30% lignite fly ash and (ii) 80% P/V glass and 20% lignite fly ash at 1200 • C for 1 h, as revealed through the use of a heating microscope.The results indicated that the P/V glass, as a sodium-potassium-rich inorganic waste, reduces the energy requirements of the melting process.The produced glass was then used for the production of glass-ceramics.Dense and homogeneous glass-ceramics, exhibiting high chemical stability and no toxicity, were produced after controlled thermal treatment of glass at 800 • C. The properties of the produced glass-ceramics (namely, water absorption and compressive strength) render them suitable for applications in the construction industry.The waste valorization approach followed in this study aligns with the circular economy principles.The possibility of using the proposed glass sets to produce mineral fibres or glass-ceramic materials was verified through a glass melting process in an electric furnace at 1450 • C for 2 h and determination of fundamental properties, such as the crystallization ability, microstructure, mechanical properties, and the acidity modulus.

Materials and Methods
The materials used in this study were melted basalt-amphibolite samples modified with a colorless glass cullet.Four sets of raw materials were prepared with the contents shown in Table 1.The prepared raw material sets were firstly homogenized and melted in an electric furnace at a temperature of 1450 • C for 2 h to obtain homogeneous glass melts.The obtained melts were cast directly onto a steel plate to ensure a high cooling rate.The chemical composition of the obtained glasses was determined through XRF spectroscopy.This study was performed using a WDXRF Axios, Malvern Panalytical Ltd., Malvern, United Kingdom; spectrometer with a 4 kW Rh lamp, and the results are shown in Table 2. Dilatometric studies were performed for the melted samples using a Sadamel DA-3, automatic dilatometer (SADAMEL SA, La Chaux-de-Fonds, Switzerland), allowing T g transformation temperature to be determined.Structural studies were carried out using FTIR spectroscopy and X-ray diffraction.IR spectra in the 400-4000 cm −1 range were obtained with a Fourier spectrometer (Bruker Optics-Vertex 70V, Billerica, MA, USA).Measurements were made employing the powder technique, and the absorption of the spectrum was recorded with 128 scans and a resolution of 4 cm −1 .The X-ray studies were performed on a SEIFERT XRD-3003 T-T X-ray diffractometer (XRD Eigenmann GmbH, Schnaittach, Germany) with a lamp with a wavelength of λ Co = 0.17902 nm at the angle range of 2θ 5-90 • .Microstructural studies were conducted employing a Keyence VHX-7000N digital microscope (Keyence, Osaka, Japan) while scanning electron microscopy SEM was performed using a JOEL JSM-6610LV microscope (Peabody, MA, USA).As part of the research, microhardness tests were also performed (HV0.05).Hardness was measured using a Shimadzu HMV-G20 (Kioto, Japan) microhardness tester with a Vickers indenter.For each sample, 10 measurements in different areas of the sample were carried out, and then the average microhardness value was determined.

Study of Amphibolite Glasses after the Melting Process
The first stage of this study was dilatometric tests to determine transformation temperature T g and softening temperature DTM for the obtained melts.The glass transition (Tg) in dilatometric tests corresponds to the inflection of the curve with a significant change in dimensions (according to ASTM E1545 [36]).The results in the form of curves are shown in Figure 1.Dilatometric studies were performed for the melted samples using a Sadamel DA-3, automatic dilatometer (SADAMEL SA, La Chaux-de-Fonds, Switzerland), allowing Tg transformation temperature to be determined.Structural studies were carried out using FTIR spectroscopy and X-ray diffraction.IR spectra in the 400-4000 cm −1 range were obtained with a Fourier spectrometer (Bruker Optics-Vertex 70V, Billerica, MA, USA).Measurements were made employing the powder technique, and the absorption of the spectrum was recorded with 128 scans and a resolution of 4 cm −1 .The X-ray studies were performed on a SEIFERT XRD-3003 T-T X-ray diffractometer (XRD Eigenmann GmbH, Schnaittach, Germany) with a lamp with a wavelength of λCo = 0.17902 nm at the angle range of 2ϴ 5-90°.Microstructural studies were conducted employing a Keyence VHX-7000N digital microscope (Keyence, Osaka, Japan) while scanning electron microscopy SEM was performed using a JOEL JSM-6610LV microscope (Peabody, MA, USA).As part of the research, microhardness tests were also performed (HV0.05).Hardness was measured using a Shimadzu HMV-G20 (Kioto, Japan) microhardness tester with a Vickers indenter.For each sample, 10 measurements in different areas of the sample were carried out, and then the average microhardness value was determined.

Study of Amphibolite Glasses after the Melting Process
The first stage of this study was dilatometric tests to determine transformation temperature Tg and softening temperature DTM for the obtained melts.The glass transition (Tg) in dilatometric tests corresponds to the inflection of the curve with a significant change in dimensions (according to ASTM E1545 [36]).The results in the form of curves are shown in Figure 1.Based on the results, it was found that the modification of basalt-amphibolite alloys by adding a cullet lowers the transformation temperature.When analyzing the chemical composition, it was found that as the cullet content increases and the proportion of amphibolite decreases, the proportion of Na2O oxide increases, which acts as a flux that affects the reduction of the transformation temperature from 670 °C (Set 1) to 633 °C (Set 4).The next stage of the research was performed for samples after melting, and the crystallization process was carried out at temperatures 800 °C, 900 °C, and 1000 °C for 2 h.Spectroscopic studies performed for structure determination of the obtained materials showed that melts contain alkali ions in their structure (Table 2), which contribute to the depolymerization of the lattice, i.e., the breaking of Si-O-Si bridge bonds, resulting in the growth of non-bridging Si-O-bonds [37].The melted samples (Figure 2a In turn, spectroscopic studies showed that the samples subjected to the crystallization process demonstrate changes in the spectra (Figure 2b-e).In addition to the distinguished three prominent absorption bands in the 1200-800 cm −1 , 800-600 cm −1 , and 600-400 cm −1 ranges, an increase in the half-width of the band in the 1200-800 cm −1 range was observed, which confirms the depolymerization of the glass bond-a reduction in the number of Si-O-Si, Si-O-Al bonds [40].The band at about 870 cm −1 and 970 cm −1 is divided into two.The change in the width of the bands and their separation may indicate the presence of crystalline phases formed as a result of the conducted crystallization process, thereby affecting the change in structure.This may indicate the formation of crystalline phases in the crystallization process of glasses, mainly pyroxenes (diopside), whose bands are at a maximum of 865 cm −1 [39,41].Based on the results, it was found that the modification of basalt-amphibolite alloys by adding a cullet lowers the transformation temperature.When analyzing the chemical composition, it was found that as the cullet content increases and the proportion of amphibolite decreases, the proportion of Na 2 O oxide increases, which acts as a flux that affects the reduction of the transformation temperature from 670 • C (Set 1) to 633 • C (Set 4).The next stage of the research was performed for samples after melting, and the crystallization process was carried out at temperatures 800 • C, 900 • C, and 1000 • C for 2 h.Spectroscopic studies performed for structure determination of the obtained materials showed that melts contain alkali ions in their structure (Table 2), which contribute to the depolymerization of the lattice, i.e., the breaking of Si-O-Si bridge bonds, resulting in the growth of non-bridging Si-O-bonds [37].The melted samples (Figure 2a In turn, spectroscopic studies showed that the samples subjected to the crystallization process demonstrate changes in the spectra (Figure 2b-e).In addition to the distinguished three prominent absorption bands in the 1200-800 cm −1 , 800-600 cm −1 , and 600-400 cm −1 ranges, an increase in the half-width of the band in the 1200-800 cm −1 range was observed, which confirms the depolymerization of the glass bond-a reduction in the number of Si-O-Si, Si-O-Al bonds [40].The band at about 870 cm −1 and 970 cm   The next step in this study was X-ray diffraction (XRD) phase analysis.The results obtained for the glasses after melting and the crystallization process are shown in Figures 3-7.As the same crystalline phases were present in all of the analyzed glasses, one example XRD result is included in this paper, with reference data for basalt glass annealed at 1000 • /2 h (Figure 3).The next step in this study was X-ray diffraction (XRD) phase analysis.The results obtained for the glasses after melting and the crystallization process are shown in Figures 3-7.As the same crystalline phases were present in all of the analyzed glasses, one example XRD result is included in this paper, with reference data for basalt glass annealed at 1000°/2 h (Figure 3).The next step in this study was X-ray diffraction (XRD) phase analysis.The results obtained for the glasses after melting and the crystallization process are shown in Figures 3-7.As the same crystalline phases were present in all of the analyzed glasses, one example XRD result is included in this paper, with reference data for basalt glass annealed at 1000°/2 h (Figure 3).The XRD results found that the materials received after the melting process do not show any peaks, indicating the participation of crystalline phases.Only an elevation of the background in the range of 20-35° 2Θ is visible, which indicates the amorphous structure of the obtained materials.The glasses subjected to crystallization showed the presence of peaks originating from the forming crystalline phases.The proportion of crystalline phases at lower processing temperatures is insignificant.The diffractograms for the materials annealed at higher temperatures show clear, sharp peaks originating from crystalline phases, mainly represented by pyroxenes and olivines.The obtained materials are characterized by a high content of Ca 2+ , Mg 2+ and Fe + , Al ions (Table 2), which explains the crystallization of pyroxene phases (diopside, augite type) [42], as confirmed by the results of spectroscopic studies too.The XRD results determined the proportion of amorphous and crystalline phases for the analyzed glasses undergoing crystallization.Rietveld analysis was used for this purpose.The results obtained are summarized in Table 3.To confirm these findings, further microscopic observations (Digital Microscopy and SEM/EDS) were performed to determine changes in the microstructures of the analyzed samples before and after the crystallization process.The results are shown in Figures 8-11.The XRD results found that the materials received after the melting process do not show any peaks, indicating the participation of crystalline phases.Only an elevation of the background in the range of 20-35 • 2Θ is visible, which indicates the amorphous structure of the obtained materials.The glasses subjected to crystallization showed the presence of peaks originating from the forming crystalline phases.The proportion of crystalline phases at lower processing temperatures is insignificant.The diffractograms for the materials annealed at higher temperatures show clear, sharp peaks originating from crystalline phases, mainly represented by pyroxenes and olivines.The obtained materials are characterized by a high content of Ca 2+ , Mg 2+ and Fe + , Al ions (Table 2), which explains the crystallization of pyroxene phases (diopside, augite type) [42], as confirmed by the results of spectroscopic studies too.The XRD results determined the proportion of amorphous and crystalline phases for the analyzed glasses undergoing crystallization.Rietveld analysis was used for this purpose.The results obtained are summarized in Table 3.
Table 3.The percentage of the crystalline phase calculated according to Rietveld's least squares approach.

Glass
Degree of Crystallization (%) 800 To confirm these findings, further microscopic observations (Digital Microscopy and SEM/EDS) were performed to determine changes in the microstructures of the analyzed samples before and after the crystallization process.The results are shown in Figures 8-11.No crystalline phases were observed in the microstructure of the melted samples for any of the sets from 1 to 4 (Figures 8a, 9a, 10a, and 11a).The samples produced from Set 2 (50 wt.% basalts, 40 wt.% amphibolite, 10 wt.% glass cullet) annealed at 800 °C for 2 h (Figures 8b, 9b, 10b, and 11b) show the presence of crystalline phases, while Set 3 (50 wt.% basalt, 30 wt.% amphibolite, 20 wt.% glass cullet) and Set 4 (50 wt.% basalt, 20 wt.% wt.amphibolite, 30 wt.% glass cullet) show opacity and demixing as a first stage crystallization.Annealing the samples at 900 °C (Figure 10a-d) and 1000 °C (Figure 11a-d) for 2 h results in the apparent crystalline phases.Upon increasing the annealing temperature and time, a rise in the proportion of crystalline phases and volumetric crystallization of the glasses was observed.Microstructure studies were also performed using SEM-EDS to identify the crystalline phases fully.Figure 12 shows an SEM-EDS image for glass Set 4 (50 wt.% basalt, 20 wt.% amphibolite, 30 wt.% glass cullet.).The EDS analysis confirms the presence of a crystalline phase represented by pyroxenes.This is very beneficial from the mechanical properties point of view of the obtained glass-ceramic materials from the CAS system [24][25][26].No crystalline phases were observed in the microstructure of the melted samples for any of the sets from 1 to 4 (Figures 8a-11a).The samples produced from Set 2 (50 wt.% basalts, 40 wt.% amphibolite, 10 wt.% glass cullet) annealed at 800 • C for 2 h (Figures 8b-11b) show the presence of crystalline phases, while Set 3 (50 wt.% basalt, 30 wt.% amphibolite, 20 wt.% glass cullet) and Set 4 (50 wt.% basalt, 20 wt.% wt.amphibolite, 30 wt.% glass cullet) show opacity and demixing as a first stage crystallization.Annealing the samples at 900 • C (Figure 10a-d) and 1000 • C (Figure 11a-d) for 2 h results in the apparent crystalline phases.Upon increasing the annealing temperature and time, a rise in the proportion of crystalline phases and volumetric crystallization of the glasses was observed.Microstructure studies were also performed using SEM-EDS to identify the crystalline phases fully.Figure 12 shows an SEM-EDS image for glass Set 4 (50 wt.% basalt, 20 wt.% amphibolite, 30 wt.% glass cullet.).The EDS analysis confirms the presence of a crystalline phase represented by pyroxenes.This is very beneficial from the mechanical properties point of view of the obtained glass-ceramic materials from the CAS system [24][25][26].As part of the research, Vickers microhardness mechanical tests were realized.The average results from 10 measurement points are presented in Table 4.It was found that the melt obtained from glass 1 (100% basalt) has the highest hardness.This can be explained by the fact that glass containing 100% basalt has the highest content of MgO, which affects the high values of glass hardness and strength [43,44].For the melts subjected to the crystallization process, it was observed that the microhardness of the glassceramic materials grew with the increase in the annealing temperature, which was caused by the presence and amount of crystalline phases formed in the annealed melts.The samples annealed at 1000 °C have the highest microhardness values, which confirms that the formed crystalline phases and their quantity improve the hardness of the investigated materials.The acidity modulus (Mk), a significant factor in assessing the mineral composition of glass and an essential parameter from the mineral fibre production point of view, makes it possible to evaluate the basic properties of the raw material used in glass production.This factor is determined as the weight ratio of all acidic oxides (silica, titanium oxide, and aluminium oxide) to the sum of basic oxides (calcium, sodium, potassium, iron, and magnesium oxide) [45,46].The following relationship (1) was used to determine the acidity modulus employing the determined chemical composition (Table 2).The obtained Mk results are summarized with microhardness tests in Table 4.As part of the research, Vickers mechanical tests were realized.The average results from 10 measurement points are presented in Table 4.It was found that the melt obtained from glass 1 (100% basalt) has the highest hardness.This can be explained by the fact that glass containing 100% basalt has the highest content of MgO, which affects the high values of glass hardness and strength [43,44].For the melts subjected to the crystallization process, it was observed that the microhardness of the glass-ceramic materials grew with the increase in the annealing temperature, which was caused by the presence and amount of crystalline phases formed in the annealed melts.The samples annealed at 1000 • C have the highest microhardness values, which confirms that the formed crystalline phases and their quantity improve the hardness of the investigated materials.The acidity modulus (Mk), a significant factor in assessing the mineral composition of glass and an essential parameter from the mineral fibre production point of view, makes it possible to evaluate the basic properties of the raw material used in glass production.This factor is determined as the weight ratio of all acidic oxides (silica, titanium oxide, and aluminium oxide) to the sum of basic oxides (calcium, sodium, potassium, iron, and magnesium oxide) [45,46].The following relationship (1) was used to determine the acidity modulus employing the determined chemical composition (Table 2).The obtained M k results are summarized with microhardness tests in Table 4.The correct M k value for mineral wool production (mineral fibres, melting, and defibering) is M k > 1.2 [39].All of the raw material sets meet this condition, although the variable share of amphibolite and modification with glass cullet increase the M k .According to a study by Du P., as the acidity factor increases, the fibre formation temperature, fibre diameter, and the content of non-fibrous parts increase [47].

Conclusions
This study investigates the microstructure (SEM-EDS), phase analysis (FTIR spectroscopy, XRD), and mechanical properties of the SiO 2 -Al 2 O 3 -CaO-MgO-Fe 2 O 3 multicomponent system glass materials.Based on this research, the proposed raw material sets can successfully find application in producing mineral fibres and novel glass-ceramic materials.Spectroscopic studies of the melted sets revealed the presence of three leading absorption bands in the following ranges: 1200-800 cm −1 , 800-600 cm −1 , and 600-400 cm −1 .After the controlled crystallization process, an increase in the half-width of the band in the 1200-800 cm −1 range was observed, confirming the depolymerization of the glass bond and a decrease in the number of Si-O-Si, Si-O-Al bonds.In contrast, the band at about 870 cm −1 and 970 cm −1 separates in two.The change in the width of the bands and their separation suggest the presence of crystalline phases and a change in the structure of the materials-the formation of crystalline phases during the crystallization process of glasses.These phases are represented by pyroxenes (diopside), whose bands are located at a maximum of 865 cm −1 , which was confirmed by X-ray and SEM/EDS phase and microstructural results.The melt obtained from glass set 1 (100 wt.% basalt) has the highest hardness owing to the increased CaO, MgO content.For the melts subjected to crystallization, it was observed that the microhardness of glass-crystalline materials rises with increasing annealing temperature.The samples annealed at 1000 • C have the highest mechanical properties (microhardness), which confirms that the crystalline phases formed and their amount improves the hardness of the studied materials.Unfortunately, due to an excessively high acid modulus, the glasses obtained are not quite optimal materials suitable for producing mineral fibres.However, the results obtained will be the preliminary base for further studies in which the authors investigate the production of porous, insulating glass-ceramics materials and mineral fibres.
) are characterized by three prominent absorption bands, where their maxima are located at about 940, 715, and 411 cm −1 .The most intense absorption bands in the 1200-800 cm −1 range can come from the vibration of Si-O-(Al) and Si-O-(Si) bridges.The absorption bands in the 800-650 cm −1 range, characterized by lower intensity, come from symmetric bending vibrations of Si-O-Si.The 650-400 cm −1 band corresponds to O-Al-O and O-Si-O bending vibrations [38-40].
) are characterized by three prominent absorption bands, where their maxima are located at about 940, 715, and 411 cm −1 .The most intense absorption bands in the 1200-800 cm −1 range can come from the vibration of Si-O-(Al) and Si-O-(Si) bridges.The absorption bands in the 800-650 cm −1 range, characterized by lower intensity, come from symmetric bending vibrations of Si-O-Si.The 650-400 cm −1 band corresponds to O-Al-O and O-Si-O bending vibrations [38-40].
−1 is divided into two.The change in the width of the bands and their separation may indicate the presence of crystalline phases formed as a result of the conducted crystallization process, thereby affecting the change in structure.This may indicate the formation of crystalline phases in the crystallization process of glasses, mainly pyroxenes (diopside), whose bands are at a maximum of 865 cm −1 [39,41].

Table 1 .
Raw material sets used for melting of multicomponent glasses (%).

Table 3 .
The percentage of the crystalline phase calculated according to Rietveld's least squares approach.

Table 4 .
Microhardness and acidity modulus M k parameter of SiO 2 -Al 2 O 3 -CaO-MgO-Fe 2 O 3 multicomponent glasses after melting and crystallization processes.